Gene conversion between duplicated genetic elements in yeast

Structural comparison of the yeast cell division cycle gene CDC4 and a related pseudogene

The function of the cell division cycle gene, CDC4, is required in Saccharomyces cerevisiae for progression beyond the G1 phase of the cell cycle. The wild-type gene was isolated from a plasmid library by selection for complementation of a recessive, temperature-sensitive allele. Hybridization of genomic sequences with the cloned gene revealed the presence of a duplicated sequence. Both CDC4 and the duplicated sequence were subjected to DNA sequence analysis. These analyses revealed (1) that CDC4 contains a large open reading frame encoding a protein of 779 amino acids, and (2) that the duplicated sequence bears strong homology with the carboxy-terminal segment of this open reading frame. Presence of a nonsense codon within the duplicated sequence suggested that it does not encode a functional product. Disruption of the duplicated sequence within the yeast genome provided a more critical test for function. The absence of any detectable phenotype for this disruption confirms that the sequence should be considered a pseudogene. The marker inserted to disrupt the sequence also served to map the duplication and to establish that it is not genetically linked to CDC4. The structural features determined suggest evolutionary relationships between these genes as well as between the CDC4 product and other proteins.

Concerted deletions and inversions are caused by mitotic recombination between delta sequences in Saccharomyces cerevisiae

Deletions of a tyrosine tRNA suppressor gene, SUP4-o, are mediated by recombination between short repeated delta sequences in Saccharomyces cerevisiae. The arrangement of the five solo delta sequences that surround the SUP4 locus was established by DNA sequence analysis. Seven deletion classes were identified by genomic blotting. DNA sequence analysis also showed that the delta sequences within a 6.5-kilobase region of the SUP4 locus were the endpoints of these events. In three of these classes, an adjacent interval surrounded by delta sequences was inverted in concert with the deletion. The frequency of all deletion classes decreased in strains that contained mutations in the recombination and repair gene RAD52. We present two gene conversion mechanisms by which these rearrangements could have been generated. These models may also explain deletions between repeated sequences in other systems.

The sequence of a sea urchin muscle actin gene suggests a gene conversion with a cytoskeletal actin gene

We report the nucleotide sequence of the single muscle actin gene of the sea urchin Strongylocentrotus purpuratus. Comparison of the protein-coding sequence of this muscle actin gene (pSpG28) with that of two linked sea urchin cytoskeletal actin genes (pSpG17 and CyIIa) reveals a region of exceptional sequence conservation from codon 61 through codon 120. Furthermore, when silent nucleotide changes are compared, the conservation of this region is still evident (7.9% silent site differences in the conserved region vs 43.3% silent site differences in the rest of the gene when pSpG28 and CyIIa are compared), indicating that the conservation is not due to particularly stringent selection on the portion of the protein encoded by this region of the genes. These observations suggest that a gene conversion has occurred between the muscle actin gene and a cytoskeletal actin gene recently in the evolution of the sea urchin genome. Gene conversion between nonallelic actin genes may thus play a role in maintaining the homogeneity of this highly conserved gene family.

Gene conversion, unequal crossing-over and mispairing at a non-tandem duplication during meiosis of Saccharomyces cerevisiae

We have developed a novel system to examine conversion, exchange and mispairing involving a non-tandem duplication of the ade8 locus in yeast by monitoring the segregation of heterozygous markers between the duplicated sequence. Plasmid Yrp17 carries the yeast selectable markers URA3+ and TRP1+. Yrp17 derivatives with a 4 kb insert carrying ade8-18 were used to clone the mutations trp1-1 and ura3-1 by gap repair. Integrants of the resulting plasmids at the Ade8 locus were crossed to yield diploid hybrids with a non-tandem duplication of Ade8 and heterozygosity for the plasmid markers between the duplicated sequences. 1192 complete, unselected asci were analyzed and 270 exhibiting recombination of the markers contributed by the plasmid were analyzed by Southern transfers to detect changes in plasmid sequences. Twenty-seven tetrads had unequal homologous exchanges and five had unequal sister-chromatid exchanges. Seven tetrads carry an additional copy of the integrated plasmid and ten are missing one. We propose that these two classes represent conversions of the entire 11 kb plasmid, which occur after misalignment and formation of an unpaired loop. Mispairing is a frequent event, and occurs in approximately fifty percent of all meioses. The system described provides a means to determine the meiotic rules of conversion, exchange and pairing for duplicated DNA sequences.

Human U1 RNA pseudogenes may be generated by both DNA- and RNA-mediated mechanisms

Analysis of cloned human genomic loci homologous to the small nuclear RNA U1 established that such sequences are abundant and dispersed in the human genome and that only a fraction represent bona fide genes. The majority of genomic loci bear defective gene copies, or pseudogenes, which contain scattered base mismatches and in some cases lack the sequence corresponding to the 3' end of U1 RNA. Although all of the U1 genes examined to date are flanked by essentially identical sequences and therefore appear to comprise a single multigene family, we present evidence for the existence of at least three structurally distinct classes of U1 pseudogenes. Class I pseudogenes had considerable flanking sequence homology with the U1 gene family and were probably derived from it by a DNA-mediated event such as gene duplication. In contrast, the U1 sequence in class II and III U1 pseudogenes was flanked by single-copy genomic sequences completely unrelated to those flanking the U1 gene family; in addition, short direct repeats flanked the class III but not the class II pseudogenes. We therefore propose that both class II and III U1 pseudogenes were generated by an RNA-mediated mechanism involving the insertion of U1 sequence information into a new chromosomal locus. We also noted that two other types of repetitive DNA sequences in eucaryotes, the Alu family in vertebrates and the ribosomal DNA insertions in Drosophila, bore a striking structural resemblance to the classes of U1 pseudogenes described here and may have been created by an RNA-mediated insertion event.

Genetic and molecular mapping of the pma1 mutation conferring vanadate resistance to the plasma membrane ATPase from Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, the pma1 mutations confers vanadate-resistance to H+-ATPase activity when measured in isolated plasma membranes. In vivo, the growth of pma1 mutants is resistant to Dio-9, ethidium bromide and guanidine derivatives. This phenotype was used to map the pma1 mutation adjacent to LEU1 gene on chromosome VII. From a cosmid library of a wild-type Saccharomyces cerevisiae genome, a large 30 kb DNA fragment was isolated by complementation of a leu1-pma1 double mutant. A 5kb HindIII fragment was subcloned and it restored both Leu+ and Pma+ phenotypes after integrative transformation. The restriction map of the 5 kb HindIII fragment and Southern blot analysis reveal that the cloned fragment contains the entire structural gene for the plasma membrane ATPase and the 5' end of the adjacent LEU1 gene. The pma1 mutation conferring vanadate-resistance is thus located in the structural gene for the plasma membrane ATPase.

Gene recombination in X-ray-sensitive hamster cells

Recombination was measured in Chinese hamster ovary (CHO-K1) cells and in the X-ray-sensitive mutants xrs1 and xrs7, which show a defect in DNA double-strand break repair. To assay recombination, pairs of derivatives of the plasmid pSV2gpt were constructed with nonoverlapping deletions in the gpt gene region and cotransferred into the different cell types. Recombination efficiencies, measured as the transformation frequency with a pair of deletion plasmids relative to that with the complete pSV2gpt plasmid, were about 6% in both CHO-K1 and the xrs mutants for plasmids linearized at a site outside the gpt gene. However, these efficiencies were substantially enhanced by the introduction of a double-strand break into the homologous region of the gpt gene in one of a pair of deletion plasmids before cotransfer. This enhancement was apparently only about half as great for the xrs cells as for CHO-K1, but variation in the data was considerable. A much larger difference between CHO-K1 and the xrs mutants was found when the DNA concentration dependence of transformation was explored. While the transformation frequency of CHO-K1 increased linearly with DNA concentration, no such increase occurred with the xrs mutants irrespective of whether complete plasmids or pairs of deletion plasmids were transferred. The fraction of cells taking up DNA, assayed autoradiographically, was similar in all cell types. Therefore we suggest that while homologous recombination of plasmid molecules may not be substantially reduced in the xrs mutants,processes involved in the stable integration of plasmid DNA into genomic DNA are significantly impaired.

Adjacent satellite DNA segments in Drosophila structure of junctions

The structure of eight satellite DNA molecules containing a junction between tandem arrays of different repeated sequences is described. In one class of junctions there was an abrupt switch with the juxtaposition of two satellite arrays. These arrays were closely related and the periodicity of repeats was maintained in phase across the junction. These arrays usually showed extreme homogeneity in their repeating sequences. A second class of junctions was more complex, and in two cases may have arisen by the insertion of a mobile element into a satellite array. A novel mechanism of satellite formation is proposed to explain the precision of junctions and sequence similarities of neighboring satellite arrays. Homogeneous satellite arrays would be generated enzymatically by synthesis of a repeat using the preceding repeat as template. Occasional errors in copying of the template, either single base changes or misreading the length of the repeat unit, would lead to abrupt switches in the repeating sequence.

Concerted deletions and inversions are caused by mitotic recombination between delta sequences in Saccharomyces cerevisiae

Deletions of a tyrosine tRNA suppressor gene, SUP4-o, are mediated by recombination between short repeated delta sequences in Saccharomyces cerevisiae. The arrangement of the five solo delta sequences that surround the SUP4 locus was established by DNA sequence analysis. Seven deletion classes were identified by genomic blotting. DNA sequence analysis also showed that the delta sequences within a 6.5-kilobase region of the SUP4 locus were the endpoints of these events. In three of these classes, an adjacent interval surrounded by delta sequences was inverted in concert with the deletion. The frequency of all deletion classes decreased in strains that contained mutations in the recombination and repair gene RAD52. We present two gene conversion mechanisms by which these rearrangements could have been generated. These models may also explain deletions between repeated sequences in other systems.

Molecular evolution of the Saccharomyces cerevisiae histone gene loci

The core histone genes of Saccharomyces cerevisiae are arranged as duplicate nonallelic sets of specifically paired genes. The identity of structural organization between the duplicated gene pairs would have its simplest evolutionary origin in the duplication of a complete locus in a single event. In such a case, the time since the duplication of one of the genes should be identical to that since duplication of the gene adjacent to it on the chromosome. A calculation of the evolutionary distances between the coding DNA sequences of the histone genes leads to a duplication paradox: The extents of sequence divergence in the silent component of third-base positions for adjacent pairs of genes are not identical. Estimates of the evolutionary distance between the two H3-H4 noncoding intergene DNA sequences are large; the divergence between the two separate sequences is indistinguishable from the divergence between either of the regions and a randomly generated permutation of itself. These results suggest that the duplication event may have occurred much earlier than previously estimated. The potential age of the duplication, and the attractive simplicity of the duplication of both the H3-H4 and the H2A-H2B gene pairs having taken place in a single event, leads to the hypothesis that modern haploid S. cerevisiae may have evolved by diploidization or fusion of two ancient fungi.

Asymmetrical pairings of transposons in and proximal to the white locus of Drosophila account for four classes of regularly occurring exchange products

An explanation for the origins of four classes of regularly occurring duplication and deficiency chromosomes is provided through examination of their molecular structures. The duplications and deficiencies occur as the reciprocal products of crossing-over, following two different patterns of asymmetrical synapsis between transposons positioned in and proximal to the white locus of Drosophila melanogaster. Three copies of the retrovirus-like transposon roo are involved in the exchanges. Evidence suggests that transposon-mediated asymmetrical exchange is a general phenomenon in eukaryotes, which adds significantly to the effects of transposons in the restructuring of eukaryotic genomes.

DNA synthesis dependent on genetic recombination: characterization of a reaction catalyzed by purified bacteriophage T4 proteins

To simulate a reaction that occurs in T4-infected cells, we have developed an in vitro DNA synthesis system that requires seven highly purified proteins encoded by this bacteriophage: the DNA polymerase "holoenzyme" (four proteins), gene 32 protein, dda DNA helicase, and uvsX protein - an enzyme that catalyzes homologous DNA pairing and is functionally homologous to the recA protein. In the reaction observed, the 3'OH end of one single-stranded DNA molecule primes DNA synthesis using a double-stranded DNA molecule of homologous sequence as the template. The uvsX protein continuously removes the new DNA chain from its template, so that DNA is synthesized by a conservative mechanism. This type of reaction, which requires the cooperation of recombination and replication enzymes, seems likely to be a general feature of DNA metabolism.

Association of reciprocal exchange with gene conversion between the repeated segments of 2-micron circle

The occurrence of reciprocal exchange of flanking DNA during gene conversion between the repeated segments of the yeast plasmid, 2-micron circle has been examined. The conversion event is induced by making a double-stranded gap within one of the repeats in vitro and allowing the gap to be repaired in vivo. The repair takes place with frequent recombination of flanking markers. Neither the topology of the plasmid substrates (linear or circular) nor the relative orientation of the repeats affects the association rule significantly. These events are reminiscent of meiotic gene conversion between homologous chromosomes but contrast sharply with mitotic or meiotic intrachromosomal gene conversion. It would appear that the difference between the outcomes of intramolecular gene conversion on a chromosome and on a plasmid gapped in vitro does not result from the different physical states of intracellular versus transformed DNA. A gene conversion event in a 2-micron circle : : Tn5 plasmid mediated by the 2-micron circle recombinase (FLP) in vivo, which is formally analogous to the yeast mating type interconversion, often results in recombination of flanking markers. The reaction can be mimicked, in the absence of FLP, by gapping the plasmid within one of the 2-micron circle repeats in vitro and carrying out gap repair in vivo.

Meiotic exchange within and between chromosomes requires a common Rec function in Saccharomyces cerevisiae

We used haploid yeast cells that express both the MATa and MAT alpha mating-type alleles and contain the spo13-1 mutation to characterize meiotic recombination within single, unpaired chromosomes in Rec+ and Rec- Saccharomyces cerevisiae. In Rec+ haploids, as in diploids, intrachromosomal recombination in the ribosomal DNA was detected in 2 to 6% of meiotic divisions, and most events were unequal reciprocal sister chromatid exchange (SCE). By contrast, intrachromosomal recombination between duplicated copies of the his4 locus occurred in approximately 30% of haploid meiotic divisions, a frequency much higher than that reported in diploids; only about one-half of the events were unequal reciprocal SCE. The spo11-1 mutation, which virtually eliminates meiotic exchange between homologs in diploid meiosis, reduced the frequency of intrachromosomal recombination in both the ribosomal DNA and the his4 duplication during meiosis by 10- to greater than 50-fold. This Rec- mutation affected all forms of recombination within chromosomes: unequal reciprocal SCE, reciprocal intrachromatid exchange, and gene conversion. Intrachromosomal recombination in spo11-1 haploids was restored by transformation with a plasmid containing the wild-type SPO11 gene. Mitotic intrachromosomal recombination frequencies were unaffected by spo11-1. This is the first demonstration of a gene product required for recombination between homologs as well as recombination within chromosomes during meiosis.

A 24-base-pair DNA sequence from the MAT locus stimulates intergenic recombination in yeast

HO nuclease is a site-specific double-strand endonuclease present in haploid Saccharomyces cerevisiae undergoing mating type interconversion. HO nuclease initiates mating type interconversion by making a double-strand break within the MAT locus. To define the recognition site for the enzyme in vitro, we have constructed a number of point mutations and deletions within or adjacent to the HO recognition site. Digestion of these substrates with HO in vitro reveals that the minimal recognition site is 18 base pairs long, although several shorter substrates and substrates containing point mutations are cleaved at low levels in vitro. A 24-base-pair HO recognition site stimulates homologous recombination when present in a region unrelated to MAT. Recombinants arise from both gene conversion and crossover events. The identification of the HO recognition site provides a way of introducing a defined initiation site for recombination.

On the origin and spread of beta-thalassemia: recurrent observation of four mutations in different ethnic groups

Seven beta-thalassemia genes were characterized after they were identified as candidates for previously undescribed mutations based upon the close association of DNA polymorphism haplotypes in the beta-globin gene cluster with specific ethnic mutations. The molecular defect in four of these genes was identical, a frameshift deletion of four nucleotides (-CTTT) within codons 41 and 42. This gene represents a common Southeast Asian mutation shared by a Laotian beta-thalassemia gene, [framework 1 (FR1)], a Vietnamese (FR1), and two Chinese patients (FR3 Asian and FR1). The deletion has been observed previously in Chinese (FR1) and Asian Indians (FR2) and is an example of independent origins of the same molecular defect, possible interallelic gene conversion (as it is seen on two different beta-globin gene frameworks in Chinese), and mutant gene migration in the Asian countries. A second example of mutant gene migration was identified in an Iranian patient with a nucleotide insertion (G) between codons 8 and 9, the same mutation previously found in an Asian Indian in the same chromosomal background. The last two genes examined represent further strong evidence for independent origins of mutation. A C-to-T substitution at position -88 in an Asian Indian has been identified previously in an American Black on a different beta-globin gene framework, and a G-to-A transition at nucleotide 1 of intervening sequence 2 found in an American Black has been observed previously on a different chromosome background in Mediterraneans. This study suggests that there are not many common beta-thalassemia mutations remaining to be discovered. It also suggests that certain sequences in the beta-globin gene are relatively mutation sensitive.

The silkmoth late chorion locus. II. Gradients of gene conversion in two paired multigene families

The late chorion locus of Bombyx mori is composed of two multigene families arranged as divergently oriented pairs irregularly spaced over 140 X 10(3) bases of DNA. The average sequence homology is 91% for the 15 members of each family. DNA sequence analysis reveals: that most of the sequence variants found in individual members of a family are shared by two or more members of that family; that family members sharing a particular variant are scattered throughout the locus; and adjacent variants in individual genes are often shared by different subsets of family members. The large number of shared variants scored and their distribution is most simply explained by numerous sequence transfers similar to gene conversions. These sequence transfers are not uniformly distributed along each gene pair. Sequence transfer is highest near the 3' end of each gene and lowest in the common 5' region between the divergent genes. A model is presented that explains these gradients by assuming that the events leading to gene conversion preferentially initiate in a simple-sequence DNA repeat. The resulting heteroduplexes extend to distances influenced by features of the sequence affecting their stability. The simple-sequence DNA is part of the major exon in both gene families and encodes tandem copies of the sequence Cys-Gly-Gly and Cys-Gly. Striking identity in the precise pattern of codon biases of these repeated sequences in the two families suggests that repeated sequence transfers occur also between families in this simple-sequence region.

Properties of spontaneous mitotic recombination occurring in the presence of the rad52-1 mutation of Saccharomyces cerevisiae

All major recombination pathways in the yeastSaccharomyces cerevisiaerequire theRAD52gene product. We have examined the effect of therad52-1mutation on spontaneous mitotic recombination between heteroalleles, and found that prototrophs are produced at frequencies significantly above reversion. This residual recombination occurs at a relatively uniform level at all of the loci examined. To help understand the role thatRAD52plays in mitotic recombination, we examined recombination between all pairwise combinations of six mutant alleles of theLYS2gene. Therad52-1mutation decreased the variation in amount of recombination between the various pairwise combinations as well as lowering the overall frequency of recombination. The reduced variation results in a different pattern of recombination inrad52-1cells than in wild type. One interpretation of these results is that theRAD52gene product, directly or indirectly, plays a role in the formation or the resolution of mismatches in heteroduplex DNA.

Mitotic recombination in germ cells generated two major histocompatibility complex mutant genes shown to be identical by RNA sequence analysis: Kbm9 and Kbm6

RNA sequencing represents a major procedural simplification for nucleotide sequence analysis of a transcribed gene. Using newly adapted mRNA and cDNA sequencing procedures, we have sequenced 855 nucleotides of Kbm9 mRNA, corresponding to the codons for the aminoterminal 285 amino acids. The inferred DNA sequence of the Kbm9 gene differs from the parental Kb sequence by single nucleotide alterations in each of codons 116 and 121, resulting in Tyr----Phe and Cys----Arg substitutions, respectively. The Kbm9 sequence is identical to that of another independently arising MHC mutant gene, Kbm6. As both the Kbm9 and Kbm6 genes were generated by recombination between the Kb and Q4 genes, our data indicate that the identical genetic interactions have occurred at least twice. The relatively large extent of identity between Q4 and Kb may be responsible for frequent recombination between the two genes. The parents of the original bm9 mutant mice had five identical mutant offspring, which can be explained by mitotic recombination in the germ cells, producing gonadal mosaicism in the C57BL/6 mother. Thus, mitotic recombination, and not meiotic recombination, appears to be responsible for the formation of at least some of the Kb mutants. Such a mechanism probably plays a major role in the generation of diversity in the major histocompatibility complex.

Inactivation of nonsense suppressor transfer RNA genes in Schizosaccharomyces pombe. Intergenic conversion and hot spots of mutation

Intergenic conversion is a mechanism for the concerted evolution of repeated DNA sequences. A new approach for the isolation of intergenic convertants of serine tRNA genes in the yeast Schizosaccharomyces pombe is described. Contrary to a previous scheme, the intergenic conversion events studied in this case need not result in functional tRNA genes. The procedure utilizes crosses of strains that are homozygous for an active UGA suppressor tRNA gene, and the resulting progeny spores are screened for loss of suppressor activity. In this way, intergenic convertants of a tRNA gene are identified that inherit varying stretches of DNA sequence from either of two other tRNA genes. The information transferred between genes includes anticodon and intron sequences. Two of the three tRNA genes involved in these information transfers are located on different chromosomes. The results indicate that intergenic conversion is a conservative process. No infidelity is observed in the nucleotide sequence transfers. This provides further evidence for the hypothesis that intergenic conversion and allelic conversion are the result of the same molecular mechanism. The screening procedure for intergenic revertants also yields spontaneous mutations that inactivate the suppressor tRNA gene. Point mutations and insertions of A occur at various sites at low frequency. In contrast, A insertions at one specific site occur with high frequency in each of the three tRNA genes. This new type of mutation hot spot is found also in vegetative cells.

Overreplication and recombination of DNA in higher eukaryotes: potential consequences and biological implications

We propose that a fundamental problem in the faithful replication of complex chromosomes of higher eukaryotes is the proper control of both the number and timing of the multiple initiations of replication on single chromosomes. When replication patterns are disrupted by any of a variety of agents, overreplication of DNA can occur. We propose a model that accounts for the generation of a wide variety of chromosomal aberrations-rearrangements, resulting from the various ways in which the overreplicated strands can undergo recombination. We also discuss certain implications of the generation of chromosomal alterations in higher eukaryotes as they may relate to cancer chemotherapy, cancer progression, aging, and rapid speciation-evolution.

Information transfer between duplicated chromosomal sequences in mammalian cells involves contiguous regions of DNA

We have investigated the nature of information transfer that appears to occur nonreciprocally between duplicated chromosomal sequences in cultured mouse L cells. We have studied gene conversion between two different defective thymidine kinase genes derived from two closely related strains of type 1 herpes simplex virus and that share a silent restriction site polymorphism. Our results demonstrate that this silent site can be coconverted along with the selected mutant sites. The findings are consistent with a mechanism of gene conversion that involves contiguous blocks of DNA differing in length, position, or both. An additional finding is that the products of coconversion events involving the silent site are unequally recovered although the rates of conversion observed at four different selected sites are similar.

Transformation of Aspergillus nidulans with a cloned, oligomycin-resistant ATP synthase subunit 9 gene

An allele (oliC31) of the A. nidulans oliC gene has been cloned using homology with the equivalent gene from N. crassa. OliC31 codes for an oligomycin-resistant, triethyltin-hypersensitive form of subunit 9 of the mitochondrial ATP synthase complex. Direct selection for oligomycin-resistance was possible following transformation of A. nidulans with the oliC31 gene. The phenotypes of transformants cultured in the presence of oligomycin were indicative of the position of integration of the transforming plasmid within the genome. Subsequent recombination events involving the integrated oliC31 gene were also apparent from altered levels of resistance to oligomycin or triethyltin. This gene should prove useful as a marker for transformation of strains lacking auxotrophic lesions and in gene replacement or disruption experiments.

Meiotic exchange within and between chromosomes requires a common Rec function in Saccharomyces cerevisiae

We used haploid yeast cells that express both the MATa and MAT alpha mating-type alleles and contain the spo13-1 mutation to characterize meiotic recombination within single, unpaired chromosomes in Rec+ and Rec- Saccharomyces cerevisiae. In Rec+ haploids, as in diploids, intrachromosomal recombination in the ribosomal DNA was detected in 2 to 6% of meiotic divisions, and most events were unequal reciprocal sister chromatid exchange (SCE). By contrast, intrachromosomal recombination between duplicated copies of the his4 locus occurred in approximately 30% of haploid meiotic divisions, a frequency much higher than that reported in diploids; only about one-half of the events were unequal reciprocal SCE. The spo11-1 mutation, which virtually eliminates meiotic exchange between homologs in diploid meiosis, reduced the frequency of intrachromosomal recombination in both the ribosomal DNA and the his4 duplication during meiosis by 10- to greater than 50-fold. This Rec- mutation affected all forms of recombination within chromosomes: unequal reciprocal SCE, reciprocal intrachromatid exchange, and gene conversion. Intrachromosomal recombination in spo11-1 haploids was restored by transformation with a plasmid containing the wild-type SPO11 gene. Mitotic intrachromosomal recombination frequencies were unaffected by spo11-1. This is the first demonstration of a gene product required for recombination between homologs as well as recombination within chromosomes during meiosis.

Trypanosoma brucei: the extent of conversion in antigen genes may be related to the DNA coding specificity

The boundaries of gene conversion in variant-specific antigen genes have been determined in six clones of Trypanosoma brucei. In each clone, antigenic switching involved interaction between two telomeric members of the AnTat 1.1 multigene family, which share extensive homology throughout their coding regions. All conversion events occurred by substitution of faithful copies of donor sequences. Conversion endpoints were nonrandomly distributed. In four clones, the 5' conversion limit was near the antigen translation initiation codon, while in three clones, the 3' conversion limit was located at the "hinge" between the two major antigen domains. In one case, two segmental conversions were involved in antigen switching. These observations reveal that antigen gene conversion can occur without generating point mutations, and suggest that postrecombinational selection may impose a limit on the number of possible rearrangements within antigen genes.

The use of plasmid DNA to probe DNA repair functions in the yeast Saccharomyces cerevisiae

The survival of plasmid YRp12 treated in vitro with ultraviolet- or gamma-radiation, or with restriction endonucleases, has been used to investigate in vivo RAD gene activity in Saccharomyces cerevisiae. Yields of pyrimidine dimers or single and double strand breaks in plasmid DNA were assayed by physical methods. The biological effects of these damages were assayed by transformation of wild-type cells and rad mutants from each of the major groups of radiosensitive mutants. After UV-irradiation plasmid survival depended qualitatively on the same host functions that are needed for cellular survival. After gamma-irradiation no such correspondence was found. Apart from a RAD52-dependent stimulation of transformation efficiency at low doses, other host repair functions had little effect. Stimulation of transformation corresponded with the production of double- but not single-strand breaks in plasmid sequences homologous with the yeast genome and may be linked with a transient increase in mitotic stability. More generally these data also show that transformation events using the LiCl protocol may entail the uptake of a very low number of plasmid molecules per cell over a 10-fold range of DNA concentrations.

Recombination events after transient infection and stable integration of DNA into mouse cells

To investigate the recombinational machinery of mammalian cells, we have constructed plasmids that can be used as substrates for homologous recombination. These plasmids contain two truncated nontandem, but overlapping, segments of the neomycin resistance gene, separated by the transcription unit for the xanthine guanine phosphoribosyl transferase gene. Recombination between the two nonfunctional neomycin gene sequences generates an intact neomycin resistance gene that is functional in both bacteria and mammalian cells. Using these plasmid substrates, we have characterized the frequencies and products of recombination events that occur in mouse 3T6 cells soon after transfection and also after stable integration of these DNAs. Among the chromosomal recombination events, we have characterized apparent deletion events that can be accounted for by intrachromatid recombination or unequal sister chromatid exchanges. Other recombination events like chromosomal inversions and possible gene conversion events in an amplification unit are also described.

Direct selection of mutants influencing gene conversion in the yeast Schizosaccharomyces pombe

In Schizosaccharomyces pombe, a suppressor-active mutation at the anticodon site of the tRNASerUCA gene sup3 leads to opal (UGA)-specific suppression. Second-site mutations (rX) in sup3 inactivate the suppressor. The sup3-UGA, rX double mutants are genetically unstable in meiotic selfings, due to the intergenic transfer of information between sup3 and the unlinked genes sup9 and sup12 (Hofer et al. 1979; Munz and Leupold 1981; Munz et al. 1982). These three genes have considerable sequence homology over about 200 base pairs (Hottinger et al. 1982). Mutants showing a decrease or an increase of the meiotic instability at sup3 have been selected. One mutation (rec3-8) increases both the genetic instability and the frequency of intragenic recombination in sup3 by one order of magnitude. It has no effect on the stability of the nonsense alleles arg1-230 (UAA), ade6-704 and ural1-61 (UGA) or on the frequency of crossing-over between sup3 and the closely linked gene cdc8. The existence of a common genetic control over intragenic recombination and genetic instability at sup3 provides a direct way of selecting for rec mutants in homothallic haploid strains of S. pombe carrying a suppressor-inactive allele of sup3. It also supports the hypothesis that the instability of mutant alleles of this gene is due to chromosome mispairing at meiosis allowing sup3 to pair with sup9 or sup12 and then to undergo recombination by gene conversion restoring the suppressor-active allele sup3-UGA from the suppressor-inactive allele sup3-UGA, rX.(ABSTRACT TRUNCATED AT 250 WORDS)

Mating-type switching in yeast is induced by thymine nucleotide depletion

Thymidylate biosynthesis was inhibited in a haploid heterothallic strain of Saccharomyces cerevisiae. When the treated cells were mixed with a haploid strain of the same mating-type, there was an increase in the recovery of diploid colonies. Genetic and biochemical analyses demonstrated that the diploid clones arose as a consequence of induced mating-type interconversion.

Formation and stability of linear plasmids in a recombination deficient strain of yeast

Natural termini from macronuclear DNA of the ciliated protozoans Tetrahymena thermophila and Oxytricha fallax can support telomere formation yeast. However, plasmids carrying these ciliate termini are modified by the addition of DNA which hybridizes to the synthetic oligonucleotide poly [d(C-A]), a sequence which also hybridizes to terminal restriction fragments from yeast chromosomes but not to Tetrahymena or Oxytricha macronuclear DNAs. Thus, in yeast, the creation of new telomeres on ciliate termini involves the acquisition of yeast-specific terminal sequences presumably by either recombination or non-templated DNA synthesis. The RAD52 gene is required for the majority of yeast mitotic and meiotic recombination events. Moreover, the absence of an active RAD52 gene product results in high rates of chromosome loss. Here we demonstrate that terminal restriction fragments from Tetrahymena macronuclear ribosomal DNA (rDNA) support the formation of modified telomeres in a yeast strain carrying a defect in the RAD52 gene. Moreover, linear plasmids bearing these modified ciliate termini are stably propagated in rad52- cells.

High-frequency meiotic gene conversion between repeated genes on nonhomologous chromosomes in yeast

We have used a genetic system that allows detection of meiotic recombination events between repeated sequences on nonhomologous chromosomes in the yeast Saccharomyces cerevisiae. We have found that recombination between these sequences occurs at a frequency of about 0.5%, and the events observed were nonreciprocal (gene conversions). Surprisingly, the frequency of conversion between the repeated genes on nonhomologous chromosomes observed in this study is similar to that observed between allelic genes. This result is discussed in connection with the role of the synaptonemal complex in meiotic recombination and with the relationship between reciprocal and nonreciprocal recombination.

Silkmoth chorion gene families contain patchwork patterns of sequence homology

The late chorion locus of Bombyx mori, containing paired members from two multigene families, has been analyzed in detail. The 15 gene pairs, irregularly spaced over 140 kilobases, exhibit an identical structure and a high overall sequence homology, while the flanking DNA (intergene regions) varies considerably. Segments of DNA of 150-300 base pairs from a reference gene pair were used as probes in a series of DNA hybridization experiments. It was found that the sequence variants within the locus are in a "patchwork" arrangement. Each gene pair contains a unique pattern of regions or "patches" that are highly homologous to the reference gene pair, interspersed with regions exhibiting less homology. We suggest that phenotypic selection is unable to account for the observed patchwork patterns; rather, sequence exchange between genes must be postulated. The nature of the DNA flanking the gene pairs would suggest that most of this sequence exchange is by means of gene conversion rather than unequal crossover events.

Antifreeze protein genes are tandemly linked and clustered in the genome of the winter flounder

We have used genomic Southern blots and restriction maps of genomic clones to examine the organization of the antifreeze protein multigene family in the winter flounder. The majority of the approximately equal to 40 antifreeze protein (AFP) genes in this fish are present in 7- to 8-kilobase-pair (kbp) elements of DNA, which are iterated as tandem direct repeats. Each repeat contains a single antifreeze protein gene that is 1 kbp long, and all of these genes have the same transcriptional orientation. Although the repeated elements are highly homologous, they do show some restriction site and restriction length polymorphisms. When flounder genomic DNA is digested with restriction endonucleases that do not cut within the repeats, most of the antifreeze protein genes reside in fragments that are at least 40 kbp long, representing clusters of five or more repeats in tandem. After genomic DNA is digested with Xba I or Xho I, these genes are present in fragments of exceptionally high molecular weight, suggesting that the clusters themselves are grouped together in the genome. The AFP gene locus may have evolved by gene amplification as recently as 10(6) years ago in response to the onset of the Cenozoic ice age.

Recombination events after transient infection and stable integration of DNA into mouse cells

To investigate the recombinational machinery of mammalian cells, we have constructed plasmids that can be used as substrates for homologous recombination. These plasmids contain two truncated nontandem, but overlapping, segments of the neomycin resistance gene, separated by the transcription unit for the xanthine guanine phosphoribosyl transferase gene. Recombination between the two nonfunctional neomycin gene sequences generates an intact neomycin resistance gene that is functional in both bacteria and mammalian cells. Using these plasmid substrates, we have characterized the frequencies and products of recombination events that occur in mouse 3T6 cells soon after transfection and also after stable integration of these DNAs. Among the chromosomal recombination events, we have characterized apparent deletion events that can be accounted for by intrachromatid recombination or unequal sister chromatid exchanges. Other recombination events like chromosomal inversions and possible gene conversion events in an amplification unit are also described.

Concerted evolution of tRNA genes: intergenic conversion among three unlinked serine tRNA genes in S. pombe

In many cases the multiple genes coding for one specific tRNA are dispersed throughout the genome. The members of such a gene family nevertheless maintain a common nucleotide sequence during evolution. A major mechanism contributing to this concerted evolution is intergenic conversion. Here we show that it occurs between three tRNA genes of related sequence residing on different chromosomes of Schizosaccharomyces pombe. Sequence analysis of converted genes indicates that blocks of a minimal length of 18-33 bp and of a maximal length of 190 bp can be transferred from one gene to the other. During meiosis the frequency of these transfers lies in the order of 10(-5) per progeny spore. Information transfer between any two members of the gene family occurs in both directions.

Identification of regulatory regions within the Ty1 transposable element that regulate iso-2-cytochrome c production in the CYC7-H2 yeast mutant

The CYC7-H2 mutation in the yeast Saccharomyces cerevisiae was caused by insertion of a Ty1 transposable element in front of the iso-2-cytochrome c structural gene, CYC7. The Ty1 insertion places iso-2-cytochrome c production under control of regulatory signals that are normally required for mating functions in yeast cells. We have investigated the regions of the Ty1 insertion that are responsible for the aberrant production of iso-2-cytochrome c in the CYC7-H2 mutant. Five alterations of the CYC7-H2 gene were obtained by specific restriction endonuclease cleavage of the cloned DNA and ligation of appropriate fragments. The CYC7+, CYC7-H2, and modified CYC7-H2 genes were each inserted into the yeast vector YIp5 and used to transform a cytochrome c-deficient yeast strain. Expression and regulation of each allele integrated at the CYC7 locus have been compared in vivo by determination of the amount of iso-2-cytochrome c produced. These results show that distal regions of the Ty1 element are not essential for the CYC7-H2 overproducing phenotype. In contrast, alterations in the vicinity of the proximal Ty1 junction abolish the CYC7-H2 expression and give rise to different phenotypes.

DNA polymorphism and molecular pathology of the human globin gene clusters

In the past few years there has been intensive study of the human globin genes. This study has provided important insights into normal gene structure and function and the nature of molecular defects leading to a set of inherited diseases. In turn, this information forms the basis for rational design of specific tests for prenatal diagnosis of particular forms of beta-thalassemia. Several areas demand further investigation. First, we need to know more about the region within the beta-gene cluster in which recombination appears to be more frequent than in areas surrounding it. This will provide new insights into the evolution of a segment of the genome and aid in explaining how particular mutations are dispersed to numerous chromosome types. Second, study of additional beta-thalassemia genes from human populations not previously studied will provide new gene defects, some of which may yield further clues about RNA transcription and processing. In addition, some (e.g., the coding region substitutions that affect RNA processing) may allow identification of new mechanisms of gene dysfunction. Third, we need further refinement of prenatal diagnostic tests so that early, accurate, and simplified assessment of pregnancies at risk can be accomplished widely, particularly in those geographic regions where beta-thalassemia is especially prevalent.

DNA rearrangements of the actin gene cluster in Caenorhabditis elegans accompany reversion of three muscle mutants

We present evidence that associates dominant mutations in Caenorhabditis elegans that disrupt muscle structure and motility with a cluster of three actin genes mapped in the same region of linkage group V. We examined spontaneous and mutagen-induced wild-type revertants of these dominant alleles for alterations in the DNA of the actin gene cluster. Four of 73 revertants contain detectable DNA rearrangements within the cluster of actin genes including an insertion, a deletion and gene fusions. We postulate that these rearrangements inactivate or delete at least one gene in the cluster and consequently the original mutations are within the actin gene cluster.